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Issue 6, 2026
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Reviews of topical problems


Topological defects in active liquid crystals


Departments of Biomedical Engineering, Chemistry and Mathematics, Pennsylvania State University, 205 Hallowell Building, University Park, PA, 16802-4400, USA

A wide class of out-of-equilibrium systems comprised of interacting self-propelled agents is termed active matter. The most relevant examples include suspensions of microscopic swimming organisms (bacteria, sperm cells, or unicellular algae), synthetic catalytic nanomotors, colloidal self-propelled Janus particles, and even macroscopic bird flocks, fish schools, or human crowds. The simplest and most studied realization of active matter is a suspension of microscopic swimmers, such as motile microorganisms or self-phoretic colloids. A liquid crystal, a highly-structured anisotropic environment with local molecular ordering, "doped" by a small amount of active component yields an interesting class of non-equilibrium materials with novel optical and mechanical properties. Singularities of local molecular orientation, or topological defects, play an important role in the spatiotemporal organization of active liquid crystals. This study surveys the most recent experimental and theoretical advances in the field of active liquid crystals and highlights connections with other nonequilibrium physical and biological systems.

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Fulltext is also available at DOI: 10.3367/UFNe.2018.10.038433
Keywords: microswimmers, liquid crystals, topological defects, active matter, collective motion
PACS: 42.70.Df, 47.20.−k, 47.63.Gd (all)
DOI: 10.3367/UFNe.2018.10.038433
URL: https://ufn.ru/en/articles/2019/9/c/
000504893200003
2-s2.0-85080942488
2019PhyU...62..892A
Citation: Aranson I S "Topological defects in active liquid crystals" Phys. Usp. 62 892–909 (2019)
BibTexBibNote ® (generic)BibNote ® (RIS)MedlineRefWorks

Received: 7th, July 2018, revised: 22nd, September 2018, 4th, October 2018

Îðèãèíàë: Àðàíñîí È Ñ «Òîïîëîãè÷åñêèå äåôåêòû â àêòèâíûõ æèäêèõ êðèñòàëëàõ» ÓÔÍ 189 955–975 (2019); DOI: 10.3367/UFNr.2018.10.038433

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  1. Robin Hu Y -M, Ostrovskaya E A et al Opt. Express 34 (7) 13580 (2026)
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  3. Bo W, Hao Y et al Soft Matter 22 (14) 2713 (2026)
  4. Kongklad G, Molahalli V et al Adv Materials Inter 13 (11) (2026)
  5. Liu L, Wu J et al Acta Phys. Sin. 75 (16) 0 (2026)
  6. He 何 K-X 凯, Ni 倪 Q-Y 琦 et al Chinese Phys. B 34 (7) 076401 (2025)
  7. Miyoshi H, Miyazako H, Nara T SIAM J. Appl. Math. 85 (6) 2636 (2025)
  8. te Vrugt Michael, Wittkowski R Eur. Phys. J. E 48 (2-3) (2025)
  9. Miyoshi H, Miyazako H, Nara T Proc. R. Soc. A. 480 (2300) (2024)
  10. Singh Sh Handbook of Liquid Crystals—Volume II Chapter 6 (2024) p. 285
  11. Delev V A, Scaldin O A, Timirov Yu I Jetp Lett. 119 (1) 58 (2024)
  12. Zhou L, Zhong T et al Adv Funct Materials 34 (42) (2024)
  13. Chandler T G J, Spagnolie S E J. Fluid Mech. 967 (2023)
  14. Macías-Durán Je, Duarte-Alaniz V, Híjar H Soft Matter 19 (42) 8052 (2023)
  15. Sluckin T J Liquid Crystals Reviews 11 (1-2) 74 (2023)
  16. Figueroa-Morales N, Genkin M M et al Commun Phys 5 (1) (2022)
  17. Schimming C D, Viñals J Soft Matter 18 (11) 2234 (2022)
  18. Katuri Ja, Snezhko A, Sokolov A Soft Matter 18 (45) 8641 (2022)
  19. Veretenov N A, Rosanov N N, Fedorov S V Phys.-Usp. 65 (2) 131 (2022)
  20. Alert R, Casademunt Ja, Joanny Je-F Annu. Rev. Condens. Matter Phys. 13 (1) 143 (2022)
  21. Copenhagen K, Alert R et al Nat. Phys. 17 (2) 211 (2021)
  22. Eroshenko Yu N Phys.-Usp. 64 (3) 321 (2021)
  23. Faidiuk Yu, Skivka L et al Phys. Rev. E 104 (5) (2021)
  24. Schimming C D, Viñals J Phys. Rev. E 102 (1) (2020)
  25. Vetrov S Ya, Timofeev I V, Shabanov V F Phys.-Usp. 63 (1) 33 (2020)
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